Mechanical Systems M.C NESTOR RAMIREZ MORALES. CONTENT ▪ Concepts ▪ Aplications of Mechanical Systems ▪ Motion and power transmission systems.

Presentación del tema: "Mechanical Systems M.C NESTOR RAMIREZ MORALES. CONTENT ▪ Concepts ▪ Aplications of Mechanical Systems ▪ Motion and power transmission systems."— Transcripción de la presentación:

1 Mechanical Systems M.C NESTOR RAMIREZ MORALES

2 CONTENT ▪ Concepts ▪ Aplications of Mechanical Systems ▪ Motion and power transmission systems

3 Concepts Machinery Kinetics The study of forces on systems in motion Kinematics The study of motion without regard of forces

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5 But…why is analyzed separate? ▪ These two concepts are really not physically separable. ▪ In engineering design is valid in practice to first consider the desired kinematic motions and their consequences. ▪ Then subsequently investigate the kinetic forces associated with those motions.

6 main purpose… ▪ One principal aim of kinematics is to create (design) the desired motions of the subject mechanical parts and then mathematically compute the positions, velocities, and accelerations which those motions will create on the parts.

7 Aplications of Mechanical Systems

8 Mechanisms And Machines mechanism ▪ A mechanism is a device which transforms motion to some desirable pattern and typically develops very low forces and transmits little power.

9 Mechanisms And Machines machine ▪ A machine typically contains mechanisms which are designed to provide significant forces and transmit significant power

10 Some examples mechanisms ▪ Some examples of common mechanisms are a pencil sharpener, a camera shutter, an analog clock, a folding chair, an adjustable desk lamp, and an umbrella machines ▪ Some examples of machines which possess motions similar to the mechanisms listed above are a food blender, a bank vault door, an automobile transmission, a bulldozer, a robot, and an amusement park ride.

11 Classification of Mechanisms ▪ Based on the nature of output speed ▪ Uniform motion mechanism. ▪ Non-uniform motion mechanism.

12 Uniform Motion Mechanisms ▪ Uniform Motion – Equal Displacement For Equal Time Interval. ▪ Examples : All Gear Drives All Chain Drives Belt Drives without slip

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14 Non-Uniform Motion Mechanisms Non-Uniform Motion – Unequal Displacement For Equal Time Interval Examples : Linkage Mechanisms Cam Mechanisms Geneva Wheel

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18 Classification of mechanisms Based on mobility (D.O.F) of the mechanism 1. Considering the D.O.F. of output only a) Constrained Mechanism b) Unconstrained Mechanism 2. Considering the sum of the D.O.F. Of input and output motions a) Single (one) d.o.f. mechanism b) Multi-d.o.f. mechanism

19 Constrained Mechanism One independent output motion. Output member is constrained to move in a particular manner only. Example: Four-bar mechanism Slider Crank Mechanism Five-bar mechanism with two inputs

20 Unconstrained mechanism Output motion has more than one D.O.F. Example: Automobile Differential during turning the vehicle on a curve Five-bar mechanism with one input

21 Single D.O.F Mechanism Sum of the input and output D.O.F. is two. Single D.O.F. Motion - One Independent Input motion and one independent output motion Examples : Four-Bar Mechanism Cam-Follower Mechanism

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24 KINEMATICS FUNDAMENTALS (CHAPTER 2) ▪ DEGREES OF FREEDOM – Any mechanical system can be classified according to the number of degrees of freedom (DOF) which it possesses. ▪ The system's DOF is equal to the number of independent parameters (measurements) which are needed to uniquely define its position inspace at any instant of time.

25 A RIGID BODY IN A PLANE HAS A THREE DOF

26 ▪ Now allow the pencil to exist in a three-dimensional world. Hold it above your desktop and move it about. You now will need six parameters to define its six DOF. ▪ One possible set of parameters which could be used are three lengths, (x, y, z), plus three angles ( , ,  ). ▪ Any rigid body in three-space has six degrees of freedom ▪ Any rigid body in three-space has six degrees of freedom. Try to identify these six DOF by moving your pencil or pen with respect to your desktop. ▪ We cannot determine deformations of a body until we define its size, shape,material properties, and loadings.

27 TYPES OF MOTION ▪ A rigid body free to move within a reference frame will, in the general case, have complex motion, which is a simultaneous combination of rotation and translation. ▪ In three-dimensional space, there may be rotation about any axis (any skew axis or one of the three principal axes) and also simultaneous translation which can be resolved into components along three axes. ▪ In a plane, or two-dimensional space, complex motion becomes a combination of simultaneous rotation about one axis (perpendicular to the plane) and also translation resolved into components along two axes in the plane

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29 LINKS, JOINTS, AND KINEMATIC CHAINS linkage design ▪ We will begin our exploration of the kinematics of mechanisms with an investigation of the subject of linkage design. ▪ Linkages are the basic building blocks of all mechanisms.